How Right IS Veritasium?! Don't Electrons Push Each Other??

Great job editing our conversations! I think it represents our main points well. And the whiteboard animations make things much clearer - nice work!

I like that you both understood the question better by your discussion.

ElectroBOOM just gave us a master class in how to conduct yourself as a scientist as well as a person. He wasn’t afraid to admit when he was wrong, was open to ideas that seemed to contradict his own, but also stuck to his guns and was able to incorporate the new ideas to agree with his already established ones.

The amount of respect you show Derek is really admirable, it is so easy for people (me included) to reject ideas that contradict our views. Props to you for looking into this with genuine interest

Great discussion!

very interesting discussion! 👏
looking forward to see your test!

Probably a whole lot of us older nerds remember literally being taught to think of the wire as a tube full of ping pong balls (or marbles) pushing each other through a tube. I'm sure at least a couple of our teachers understood this as a *model* through which to visualize the process, but lots of them and us (including me back then, I'm positive) took it as an actual description of what the electrons were doing. Kind of how most people believe atoms are tiny spheres with tinier spheres rotating around them.

Amazing discussion. I loved the way you both compliment each other. I’m learning both electricity and how to respect each other. Kudos

The issue with those kinds of questions, is that they are overly simplified. Which always leads to endless discussions. The discussion perfectly shows that as well.

While getting my undergrad in EE i was always conflicted by these questions. Then when i started making semiconductors(TFTs) it just clicked. Conductivity is determined by either electron density or electron mobility. The electric fields are what is providing the work. Moving electrons create more fields which increase the fields hence why we have propogation delay in signals. High electron mobility means the electrons can follow the fields longer before crashing which means higher conductivity.

You guys are awesome 😁
It's really nice to see a polite and honest conversation.

16:11 i think a helpful analogy for the surfaces charges applying the force that moves all of electrons is one of those “bladeless” fans. those fans work with a fan in its base speeding up air. this moving air is then ducted into a ring. due to the viscous affects, the air that originated from the base fan imparts its energy to the static air inside the ring. this means that a small amount of faster moving air from the ring results in all the air moving at a slower rate. the most of the air is static until viscous forces move it. this is like the charges inside the wire. they do not have net movement on their own but with the surfaces charges they do move. and based on the book these inner charges make up a majority of the current. just like in the fan the originally static air has more mass than the fast air from fan in the base. also the air from the fan does also move like the surfaces charges

An amazing conversation, and the editing adds a lot of context someone might need to fully understand it. Great video!

I really love how one video by Veritasium triggered this whole peer review and productive discussion process. Especially because we, the audience, normally aren't shown that incredibly important part of science. Being wrong, or just being misunderstood, and needing to elaborate. Discuss with fellow scientists, come to new conclusions, and be able to explain better than before. All we are usually presented are the conclusions that remain at the end of this process. Not this time. Veritasium, Electroboom, Steve Mould, and all the others made this so much better than just explaining a physics problem, by showing us how scientists interact with each other. Thank you!

Loved the colab! Way better than video/response. Good work, guys!

This video is amazing. A topic like this which would normally be mundane; you manage to add so much too it with the edits that it becomes amazingly engaging even for people that aren’t that interested in the topic. Splendid.

I appreciate that this is simply a humble discussion between you two. And that humbleness is what keeps me coming back Mehdi!

I have been following this discussion for a while now and it's nice to see the both of you reaching a unified outcome. It's all about education! My Grandfather use to always say, "If you don't learn something new everyday then it's not worth living."

It's important to distinguish high frequency current from DC current. It's the high frequency field current (coming from the switch action) that flows on the surface of the wire (skin depth phenomenon) and propagates through air on a shortcut to the light bulb. This is why a smaller potential is seen first before the DC field current makes its way around through the bulk of the wire.

This was such an epic back and forth I learned more from both of you than I could have learned from just one or the other

The editing was superb and the conversation was great showing the way you guys bounced ideas off each other

This has been one of my favorite CZcams “dramas” to follow. Amazing conversations and perspectives from many parties. I studied conventional and electron theory in college but I feel like I have learned a whole lot more from this “series”. I love it.

@ElectroBOOM. There is also another information you could add to your analysis. About electrons being able to push something, you may investigate the electromigration phenomena, where electrons transfer momentum to the ions present in very thin conductors (again, as you said, it depends on what do you call push).

Derek`s explanation of currents flowing over wires much reminds me of how currents flow through our bodies: by subtle disturbances of the charges around a membrane. It`s as if in our bodies the inside of the wires, being electrically neutral, serve other cellular functions, thus making for much better use of space and allowing for "intelligent wires" which change their properties based on how cell membrane and other changes induce changes in the ambient surrounding the membrane and the membrane properties.

This is tremendously interesting and I love the more in-depth, nuanced electrical discussions. This video was edited very well and kept everything understandable, great visuals.

Regardless of your views on the nature of electricity and charge gradient in conductors,
*this is a tremendously important video* because it shows two intelligent adults having a civic, relevant and pertinent discussion.
Very nice collab 👍

Your conversation really helps - THANK YOU.

I could understand more before I saw this video! I think that the explanation with "push and pull" and the one with electric field are equal, because they are just different theories representing the same phenomana. But, I think using electric field to understand this is better, because field can represent the situation more correctly where all the electrons contribute to the field and are affected by it, which mean this explanation include all the objects, electrons, protons and a battery, whereas "push and pull" theory only consider close particles as approximation. But, still they are the same!

Where the field point of view DOES matter in EE design is when looking at PCB design, particularly where the return current flows in a circuit trace over a GND plane below (particularly for higher frequencies). The current associated with a changing signal (e.g. a pulse through the trace) in the GND plane is actually right below the trace, as it is caused by the changing field by the trace. So even if the trace meanders and zigzags all over the PCB, the return current to close the circuit through the GND plane does not choose the shortest path between the contact points, but also follows a meandering zigzagging path as dictated by the field, which follows the path of the circuit trace. Further, if you imagine sending a pulse through a trace, through a load, and then back through the GND plane, the pulse does not travel in a circle out to the load and then back through GND, like a marble on a marble track, or like water through a hose.
Rather, as the pulse starts traveling along the trace, AT THE SAME TIME an opposite return current starts forming underneath the trace, traveling in unison with the signal, until it reaches the load. This is exactly like the Veritasium thought experiment - current right under the trace in the GND plane starts flowing right underneath the trace, in parallel with the changing signal. Robert Feranec has a few very good videos on the topic. czcams.com/video/4nEd1jTTIUQ/video.html
For me at least, this was really a mental switch where it "clicked" - the intuitive idea of "electrons pushing through wires", or even, kinda like water going through pipes, didn't make sense to explain what's actually going on, but thinking in terms of fields, and where those fields are, does really help to understand. This is hugely important when designing HF or RF PCBs, and for EMI compliance (and yes, even an 8Mhz ATMega is high frequency, as the clock edges change within nanoseconds, i.e. 100s of Mhz with harmonics in GHz range).

We need more of these kinds of collabs between science communicators on CZcams! Seeing these sort of back and forth not only allow me to better understand whats going on but also contribute to the scientific community and encourage public discussion of topics that otherwise would go over my head

Very interesting to see the points on both sides. Great video!

The point about charges outside the conductor is an important one for some circuits. A good example is that I learned when setting up my sound system that you want to run the power cable for the amplifier on the opposite side of the car from the audio cable from the head unit to the amplifier. The reason is the power cable draws a strong enough amount of current from the battery that the electromagnetic field will actually cause interference with the audio signal, which in turn causes "dirty sound" as a final result.

Just like with the Steve Mould's video your reactions are perfect for me. They are not here to prove the original wrong, rather to explain a few concepts better. I usually have similar questions as you do and you research them for me, thanks!

I have a EET background, and I thought of the current of electrons in a way similar to you. A surplus of electrons in the wire close to the negative terminal pushes electrons ahead to fill holes in the wire close to the positive terminal. The longer the wire, the higher the resistance because you are needing to overcome a static resistance. If the conduit has a larger cross sectional area, i.e. a higher guage, then it lowers the resistance because some of those electrons in the matrix have the ability to move out of the way. The immediate way most people would understand what I'm saying is that the wire is like a pipe, but it is more like an inverted pipe. The electrons are moving on the surface, but the same properties hold true in that the higher guage has less resistance and that the differential gives electrons a way to overcome that internal resistance and push other electrons forward...
But superconductors change that perspective for me. A superconductor wouldn't have a gradient. You can't use a DMM and measure a voltage potential across a superconductor and yet it will still carry a current. This would suggest that since the electrons are free to move through the matrix there must be some other force moving them. If it isn't the force of a gradient applied across the conductor, then the only other obvious force would be the field. If a field applies to a superconductor, then it stands to reason that the field would apply to any conductor.
I think that the classical way of modeling electricity like water pushing through a pipe is still a good way to think about what is happening in a circuit for most circuits someone would build on a bench with a breadboard or a soldering iron, however it doesn't capture the reality of why and what is truly happening in a circuit.

I think these back-and-forth conversations are super important! Be they over a video call or videos made in reply to other videos, it keeps everyone thinking and accountable for what they say; if they make a mistake, it’s good for others to catch them!
Also maybe electrons don’t push and they’re being sucked

Awesome discussion - reading up on skin-effect in AC Transmission lines - the traditional model is quite effective in explaining so many of the practical questions around electricity…

This is awesome! Good work both of you... building quality knowledge for the world like that! It's been awesome to follow this discussion from the first Veritasium video throughout all the reviews and discussions. I think you did a grand work on putting the final conclusions into action! Kudos!

I did some of this in College and I’m glad it’s not so straightforward to you guys either, I came away with the impression that mental models are for accurately modelling outcomes for engineering and the truth is for philosophers to debate.

brilliant, thank you. It added something to see you two guys working it out between you. It did. Was a good thing. :)

I think it's great to see you clarifying your points of view but both being willing to learn.

Excellent arguments! I agree with you 100%. I can’t think of a reason the surface charges should be in bound states, and calling their current “negligible” doesn’t really help, because if that same quantity of charge were distributed (radially) through the wire as your (and my) initial mental model stated, the total axial current doesn’t change at all.
Since talking to Derek about this I’ve been trying to think of any reason they could be bound, and beyond the surface charges that are intrinsic to the material interface/workfunction/whatever that should always exist and be uniform throughout the material, there’s no reason the mobile electrons can’t push on each other.
The only bit I would add is that “batteries” don’t supply an electric field, they just pump electrons around in the most direct way possible, but with the thenevin and norton and whatnot we know it doesn’t matter 😁
I’m in the process of trying to set up a water model of exactly what you drew here on the whiteboard to demonstrate ohms law so I think we couldn’t be in closer agreement lol.
Now I need to go watch your long wire experiment - I heard from a friend of mine that’s already watched you were able to get it properly impedance matched where Derek and I both missed the mark, so I’m looking forward to it!

What I love is that they are pointing out that the accepted model (while it works very well) does present a lot of common questions which are NOT stupid and actually quite logical.

This is a nice eye opener. I always thought from my school lessons that electrons are flowing like a stream of water from the sea of electrons in a conductor material.
But we were taught in biology that electrical charge or action potential propagates in a somewhat similar manner but here electrolytes (Na, Ca, K ions) create charges.

These discussions end up being muvh more exciting than the original videos! Thanks for sharing them.

This has been so informative. Thanks for your insight and helping us understand these more complex things. You're awesome and I love your videos

These collaborations are great. Especially in the form of discussion where it's back and forth exchange of ideas and answers and explanations, which takes a lot of gaps out immediately - the follow up questions get answered or discussed right away. The ones that might be hidden from the one making an explanatory video, but a mystery to the one watching it. Great video.

Enjoyed this post. It seems to somewhat combine the electron and hole theories I was presented by one of my instructors in the early 1970's. Excellent animations and drawings!

this was the most scientific way to comment a video: an specialist arguing (his believe) with another specialist backing up his theory with citations! just amazing

Thank you Mehdi. I found this video extremely helpful. After studying EE for 3 years i find it baffeling, frustrating and also fascinating that the "simplest" concepts are very much not as simple as they seem

You guys should really include nick from “the science asylum” in this. He made a really well animated and explained video discussing all this pretty much, about 2 years ago.
He’s criminally under-subbed.

❤ love both of you guys for your amazing teachings.

The model of the charge gradient existing only on the surface of the wire is very clear when you remember the wires capacitance

About gradient having opposite effects according to each of you, I just want to point out that in electric guitar magnetic pickups, the amount of wire around the poles DOES have two conflicting effects. It results in inductance but also impedance, which means that depending on the impedance of the receiving circuit the perceived output may be higher or lower. You'll find nonsensical results such as "mixing two pickups of radically different sizes will result in the quiet one dominating the loud one" (seen in the Gibson EB3 for example)

Finally!! Great stuff! I've been teaching the "spitting/sucking electrons" model for batteries for ages, seems obvious once you've built a Daniell battery once in your life. Recharge it and look at that Zinc build up and Copper ions in the solution. The fact that the battery delivers energy through the + AND the - becomes apparent.

This was a lot of fun! Great stuff!
12/28/22

I listened to the veritasium video while working, and was so mentally upended i spent the next work hour researching this. Thank you for this video! It makes perfect sense now.

It was really a great polite discussion. I get some additional ideas about the electrons flowing in a wire and i really want to acknowledge both of you.

I love the way you do this, like with Steve Mould's chain fountain. Two people trying to prove each other wrong in a civil manner is both fun and a great way to learn!
Also a great reminder that everything in science is just models to simplify and understand complex things

Great discussion! I'm left pondering 1. inductive charging and 2. RF transmission. Neither of these share a metallic conductor between the source and load/receiver. I accept #1 as "magnetically coupled", and #2 as a propagating "EM field". Aren't these are the same fields as this thought experiment? How does it work without a conductor to hold surface charges?

I would be interested to see how these tests change as the skin depth of the conductor is altered with the frequency of the signal. I feel like being able to vary skin depth would be helpful in modeling these ideas.

This video was really helpful, the surface charge distribution now makes a lot more sense! It's awesome that you two could come to an agreement as well.

11:00 I remember asking this exact question in my middle/high school physics class. I also remember making a pretty big deal about it in my back and forth with the teacher, so this whole discussion is very interesting to me.

Beautiful discussion, more like that ❤️

Thanks Mehdi, another well-done video explaining it to the T so that a layman would understand. 👏

I've always loved watching your videos. Growing up in a poor community was extremely difficult, and my lack of self-discipline did not help my decision making. From being a gettho child who had no high school education doomed to fail, to now finishing my higher education in computer science. I want to become a cyber security specialist. I just want you to know, you're part of my inspiration.

Physics grad here. One of the engineering physics questions that totally made students insane was to calculate the average drift velocity for electrons in a wire and calculating the eclectic field in a wire.
Those questions were always MORE difficult for students that understood Kerkoffs loop laws and could model circuits well. Turn on a light and let it run for a bit turn it off. The average electron has moved and incomprehensibly short amount. Blows peoples minds. I was a tutor and every year every Professor would assign the problem. Students who rarely, if ever, came for help would come for help on the problem they "got wrong" they all thought they had an order of magnitude problem or problem with vector field modeling.
I am not surprised that people are confused with this and ALSO get the idea that it does not matter much. We teach circuits in a way that helps people understand and use them correctly. Probably using a working modle is what's MOST important.

Just a truly great video. Not antagonistic, just a legitimate, interesting discussion.

From what I read before, with DC currents, electrons flow through the wire similar to water through porous concrete. Each atom would be similar to aggregate in porous concrete. Water flows between the pebbles.
However, with AC current, the charges inside the nucleus are influenced to flip back and forth with a slight lag in timing. As momentum changes the internal atoms offer up resistance which causes flow to a lower outer resistance path provided by fields on the perimeter.

As much as I learn from your channel, these collaborations do an amazing job of helping me figure out how such seemingly simple, yet incredibly complex, topics work. Thank you, and keep up the great work!

1) What Veritasium (and ElectroBOOM) is missing is that you simply cannot separate charge from field distribution. If you look at Maxwell equations there is not way to separate one from the other. The charges move because of the field, while charges are creating the field. You can't make arguments for both, and both can give you a usable explanation within certain frames of reference, but neither charges nor fields can be considered independently.
2) Technically nothing pushes anything else by touch since the only mediators of force are the fundamentals forces of nature, and since the only one that applies at lengths larger than the nucleus of an atom is the electromagnetic force (gravity too but not of interested here), EVERYTHING is moved away by the actions of the fields link to that matter. For example: If someone slaps you in the face, it will still be the electromagnetic fields in the atoms on your friend's hand that exchange energy with your face.
3) Veritasiums problem was a trick question not because it was not correct, but because our common (and the only one with a meaningful use) understanding of when a lamp bulb is on is at the steady state. If the lamp is on or off is not a matter of physics, but a matter of agreement, and commonly we agree that the lamp is on when it is FULLY ON, when the electrons go around the whole loop. This is why the this is a trick question, because he challenges common expectations and abuses the definition of what makes a lamp being on.

This feels a little like the confusion that arises when observing waves in the ocean or atmosphere - it’s tempting to see the wave as a feature that moves and influences the flow as it does so, but in actuality the flow moves through the features, not the other way around.

This actually really helped!!

I especially like the close-up of his grey carpet as the background when the guys are chatting. Lovely. Grey carpet is very popular 👍

I love these discussions from a learning perspective. I feel like I have gotten a better understanding of current as a result of these discussions.

I've seen your shorts but didn't get around to your page. Veritasium got me here. Love your content dude. I love your respect for science.

Near field and far field EM radiation with RF antennas are a thing, so perhaps that applies at DC with extremely small field space in a conductor. You also have to take into account conductor skin effect which is more pronounced as you increase frequency.

I saw a video from a physicist AlphaPhoenix putting this to the test with 1km of wire and an oscilloscope. It showed there was an immediate movement in the wire which then grew quite significantly. If I recall about 20% of the voltage measured conformed to Veritasium's explanation whilst the rest came through at the time you'd anticipate for the more conventional description. That seems a soft confirmation of the traditional theory, but seems to be exactly what one would expect with your later explanation in this video. I wasn't convinced by Veritasium's video but your explanation makes a ton of sense to me and conforms perfectly to the evidence demonstrated. There definitely is a time component one would expect from something travelling along the wire.
The book seems a little odd to me. It describes conductors as just a binary thing rather than a spectrum. Whilst it might not matter to the description being presented it gave a lot of confusion and really wasn't too convincing for that reason. Your description gave a far better and more convincing argument. Veritasium's firm statement of "the light turns on instantly" being (mostly) wrong didn't help my understanding either I would say, even if it was trying to highlight the distinct differences in theory.
Definitely glad I watched this, seeing the debate was very productive towards my understanding. Plus you're amazing at breaking down topics in an understandable way. Very glad for these debates.

This is the internet at its best! Two minds comparing notes, both trying to improve their understanding of how the universe works, no egos getting in the way. Thank you for sharing this discussion!

Saved to rewatch. To enjoy the talk. Kudis to both!

I'm starting to study electronics by myself and understanding the field, matter relation helps me understand voltage as a 2 "sides" force so many didactic content on youtube it feels like studying in the future. I can picture the movement and energy on the circuits we use everyday. Thanks for this awesome discussions

Very interesting topic. Hope you do that test. Derek's test seemed to show that the initial voltage bump was about 4-5 v almost instantaneously and then an overshoot and drop to the applied ~20V when the main wave made it through the wire. I'd like to understand (1) if the magnitude of this initial bump is impacted by the distance between the wires. If it was 2 m or 4 m rather than 1 m apart, would the initial voltage magnitude decrease or is it somehow independent? And (2) would this initial ~25% of the voltage stay at that level or does it spike and slowly drop until the main wave from the fully wire flow gets to it. And (3) does it transfer not only a measurable voltage across a larger resistor, but does it transfer enough current through a typical light bulb type of resistance to say that it would go "on"

A ton of learning from this one. So my takeaway is: electrons probably drift slowly because they end up having a positive net force forward in a charge gradient that is caused when voltage is applied, but they don't carry significant energy, fields do. Fields propagate, electrons follow and generate the fields or something, fields do the work. There's still something to be clarified about electrons generating fields and how the fields carry energy, as well as how resistance is properly visualized as fields. Awesome you're clarifying this!

I think the concept of characteristic impedance is quite relevant to this topic. It even gives you ways to calculate inductance or capacitance given a wave velocity and impedance, or to calculate velocity given the inductance & capacitance of a line. Given a parallel resistor branch, I don't think there's any "guessing" at all, current follows the path given the characteristic impedance - at least at a coarse level. You can use E & M solvers (Microwave Office, Sonnet, HFSS, Simbian, and/or many others) to determine the behavior quite precisely, including through antenna, which is their main reason for being.

I know I’m coming months after this original discussion. I remember seeing Veritasium's original video and a couple videos after, and there is a subtlety that I think Derek (I’m likely misspelling his name) fails to mention and that is the regions of concentration of Poynting vector power. The fields are most concentrated along the contour of the wire. So, while there is power transmission across the space to the bulb, meaning that there is indeed a 1/c transmission time for the start of power dissipation at the bulb, the more significant bulk of power transmission follows the contour of the wire, meaning it takes a much longer time. There was a video where one guy did the experiment using an oscilloscope to measure the timing of the power transmission and found exactly this.
From Jackson's “Classical Electrodynamics”, we learn that conductors are defined as equipotential volumes, that is, the electric potential is the same everywhere throughout the volume of the conductor. This means the electric fields are not allowed to exist anywhere within the volume of the conductor since the electric field is the gradient of the electric potential. Should any electric field develop within the volume of the conductor, free charges will immediately respond to that field such to cancel it out (electric charges only respond to electric fields in their reference frame). So, the electrons within the conductor are always moving in response to any existent field within the conductor such to cancel the field and return the volume of the conductor to a state of being equipotential.
However, at the surface of the conductor, electric fields normal to the surface of the conductor, due to concentrations of surface charge to cancel the internal electric fields of the conductor, can exist. Further, magnetic fields near the surface are created due to the bulk movements of charge through the conductor. Both these fields have their highest magnitudes near the surface of the conductor; thus, the Poynting vector, S = ExB, will have its greatest magnitudes near the surface of the conductor.
They are both right, but I think there are some additional details to complete the picture of understanding that are being left out.

Great discussion! I also love the 4th wall break at 3:20 😂

After watching tons of old Electroboom videos, I finally found one that came out the same day I watched it.
One of the best feelings I have gotten in a long while.

I have never find a physicist more interesting and energetic than you🙏Thanks for making this video👍

Edit: This ends up being mostly covered closer to the end of the video.
It's almost like there is an equivalent description available that doesn't rely on the notion of "pushing" to describe something that can also be described as pushing depending on frame of reference. This is kinda the whole deal with gauge theory.
Spin-statistics already guarantee the electrons cannot exist in the same state, and will thus develop a pressure density when they get pushed together.
When we say "does the energy come from the particle or the field," this seems to ignore that the particle comes from the electric field that is already present in the system. A particle exerting force is no different than a field exerting force via fluctuation in a given density. The interplay of what it takes for an electron to appear as a form of energy from an electron field is already sufficient to describe whatever energy we wish to discuss. All an electron even is is a disturbance in that pre-existing field.
We don't even need to rely on the notion of particles at all to model this entire system. We can even describe it purely geometrically using coordinate-free differential geometry.

I CAN COUNT ELECTRONS! .
Hi EBOOM & Veritasium , I work with SEMs (Scanning Electron Microscope) and I must insist that the electrons do move from the negative to the positive of the power supply actually "move" pushing each other and really moving .
If this was not the case we would not get the ability to control them in vacuum using EM/ES fields or have them interact with the material they are "bombarding" .
We can even measure each electrons energy and count them (almost one by one)

Amazing video. Now let's see how in AC, the high frequency current moves around the wires. I guess it'd be very similar to this, but with all the spice of skin effect, and the rapid polarity change.

I think of electricity as either the result of a difference in voltage pressure due to resistance in a completed circuit, or as the backwards exchange of void electron particles from a resistive force.
That's why high voltage can shock you without a complete circuit: the difference in voltage pressure is so immense that the slight resistive force of your body is enough to create those void electron particles by push/pulling the stable valence shells in your body apart and travel the electronic force into a current through the newly created conducting path.
Its true about being neither a push or a pull, it's more like how a diode works. There is a simultaneous draw and pull within each molecule based around the materials resonance, individual velocities, and the constant exchange of higher velocity electrons with slower velocity ones to create equilibrium.
Diodes operate by taking advantage of different forms of electron particles either representing the void where electrons want to flow or the excess of electrons to bridge the gap.
If a diode pushed electrons then it would bridge the gap and be gaited by the amount of extra free electrons within the diode, if it pulled then the idea of a diode only working one way is kind of backwards with how we understand electron physics. Instead the excess energy in a circuit seeks to find equilibrium with any material it can exchange that energy with though that materials natural harmonic resistance as well as electronic impedance.
That might be why triangular valence shells are best for conducting current: because they will most typically exert an unbalanced but self correcting valence shell when it comes to excess energy. IE their electrons want to push the energy difference into equilibrium just as much as they want to pull the void electron particle to a new place in a conductor.

Electrons pushing each other.
Listening to the interesting dialogue I cannot help but to make my own observation with a mechanical model, after all exactly what both parties were doing. I imagine a line of people (electrons) walking in a straight line and pushing on each other with myself somewhere in the middle. We all move due to our feet pushing against the ground (potential) while at the same time I am being ‘pushed’ by the guy behind me and I am ‘pushing’ the guy in front of me. Since we are all moving at the same speed, I honestly cannot imagine feeling any pressure either on my back or on my palms. Thank you.

Great videos, I love this stuff. You might want to start this discussion from the viewpoint of a super conducting material and then slowly raise the temperature showing what is happening at the atomic level. In a super conductor both the speed of the electron and the speed of the field are equal, as the temperature rises the electrons speed decreases while the speed of the field propagation remains the same. Keep up the great work. Thanks

When I first started learning about electronics I thought charges pushed each other, but after a while it didn't made sense to me, because how would it know what path to go beforehand? So then I started to imagine charges were "sucked" from the negative side to the positive side, so the positive charges were attacting pulling the charges, while they would be pushing each other as well, and the pull from the protons would guide them.... But after reading about singnal integrity and electromagnetic compatibility, I know it was all wrong lol

Very informative! Extra points for floating head!

Derik's way of think matter because with the currents running outside the conductor, you can explain Faraday's gauge and why you are protected inside vehicles when a lightning strikes your car... Because the current flow outside the conductor, you are protected inside the car. (And, no, it is not because the tires are insulants, because at the lightning voltages, the tires become good conductors!) For the same reason, in many cases, the skin of persons stroke by lightning is burned in outside, but less inside. The transmission lines have this in mind too, because they can have less conductive cores to support the wire weight, but high conductive outside cover to conduct the current.

Great discussion. A bit lost in all this though is you keep showing a DC circuit in your animations and Derek did the same in his original example. But he refers to fields which have more effect in AC circuits. Such as his statement about power line transformers in his original video, that they don’t transfer electrons because it’s not a continuous wire. But a pure DC circuit won’t continuously transfer energy in a transformer circuit, only AC (ignoring pulsed DC circuits). So it’s really a bit of apples and oranges and why they are different but related science (Edison DC vs Tesla AC).

When you do the experiment, could you do parallel wires (as in Derek's) and also a circular loop? It would be interesting to compare the maximum effect vs the minimum

I wish I could have conversations like this irl... everybody so goddamn preoccupied with being right about everything all the time. This was entertaining and educational. love your vids.

It's nice to watch experts having a conversation. Makes me feel like I have a lot to learn.